PARENT GRANT – ABSTRACT (as per original submission) The overarching goal of our laboratory is to determine how DNA damage response inhibitors (DDRi) can be used to potentiate cancer cell killing while concurrently increasing anti-tumor immune responses after radiation therapy (XRT). The DNA Damage Response (DDR) is a signaling system that integrates DNA repair pathways and the cell cycle to safeguard genome stability. In addition to activating cell cycle checkpoints and DNA repair in cells treated with XRT, the DDR limits origin firing and delays cell cycle transitions in unstressed cells. While cyclin- dependent kinases are cell cycle accelerators, DDR kinases are cell cycle brakes and, in this analogy, DDRi disable the brakes, causing unchecked acceleration. Here we will determine how the DDR is rewired in CD8+ T cells to accommodate massive and concomitant DNA replication and transcription in S phase. We will also determine the impact of DDRi in cancer and immune cells. We hypothesize that ATR kinase inhibitors induce origin firing that causes ribonucleosides to be mis-incorporated into the genome, and that this generates chimeric RNA-DNA fragments and type I IFN-dependent immunologic memory after XRT. To test our hypothesis in cancer and immune cells, we have generated an innovative transplantable model of cancer. The Mcm4Chaos3/Chaos3 mouse carries a mutation in Mcm4 that destabilizes the replicative helicase. Cells derived from Mcm4Chaos3/Chaos3 mice have a 60% reduction in origin licensing. We have generated Mcm4Chaos3/Chaos3 B16 cancer cells that can be transplanted into Mcm4wt/wt and Mcm4Chaos3/Chaos3 mice. This will allow us to separate the function of ATR that limits origin firing from that which mediates the repair of replication forks in cancer and immune cells. In Aim 1, we will define cell cycle kinetics and determine how ATR inhibitors induce DNA damage in immune and cancer cells in vitro. In Aim 2, we will define cell cycle kinetics and determine whether ATR inhibitors induce DNA damage in immune cells and type 1 interferons in vivo. In Aim 3, we will determine whether ATR inhibitors combine with XRT to generate durable responses and immunologic memory through effects on immune and/or cancer cells. Successful completion of this project will define how the DDR is rewired in CD8+ T cells to accelerate cell cycle transitions and accommodate massive and concomitant DNA replication and transcription in S phase which, accounts for ~70% of the cell cycle as G1 is abridged. These studies are highly significant as the objective of checkpoint blockade and adoptive T cell transfer is to induce rapid division in CD8+ T cells. Successful completion of this project will identify combinations and sequences of DDRi that potentiate cancer cell killing while concurrently increasing anti-tumor immune responses in mouse models of cancer treated with XRT. These studies are highly significant as we use DDRi that are currently in 115 clinical trials a...